Shock tube and modeling study on the ignition delay times of ammonia/dimethoxymethane at high temperature

The ignition delay times (IDTs) of ammonia/dimethoxymethane (DMM) mixtures at DMM blending ratios of 5%, 10%, 15%, and 50% are measured behind reflected shock waves under the following conditions: pressures of 1 and 10 bar; equivalence ratio (& phi;) of 0.5; temperatures between 1193 and 1852 K. The DMM-NH3 model is proposed including the DMM subset, the NH3 subset, and the cross-reactions be-tween DMM and NH3. The cross-reactions consist of the prompt NO and reburn reactions, recombination reactions, H-abstraction reactions, and disproportionation reactions. The DMM-NH3 model well predicts the IDTs and laminar flame speeds (LFSs) of NH3 /DMM mixtures measured in this study and those from the literature. And the DMM-NH3 model is also validated by the IDTs, LFSs, and species profiles of pure NH3 and pure DMM reported in the literature. The effects of the prompt NO and reburn reactions, re-combination reactions, H-abstraction reactions, and disproportionation reactions are discussed in detail. The NH3 /DMM oxidation pathway is also analyzed.Novelty and Significance Statement ➢ The IDTs of NH3 /DMM mixtures at high temperature are measured.➢ The detailed DMM-NH3 model is proposed with the addition of the cross-reactions between DMM and NH3.➢ The DMM-NH3 model well predicts the IDTs and LFSs of NH3 /DMM mixtures.➢ The prompt NO and reburn reactions and the recombination reactions have negligible influence on the ignition.➢ The H-abstraction reactions slightly inhibit ignition and the inhibiting effects come from CH3OCH2OCH3 + NH2 = CH3OCH2OCH2 + NH3 (R1591).➢ The disproportionation reactions significantly inhibit ignition and flame propagation, and the inhibit-ing effects come from HCO + NH2 = CO + NH3 (R1629).& COPY; 2023 Published by Elsevier Inc. on behalf of The Combustion Institute.

Automated summary

The ignition delay times (IDTs) of NH3/DMM mixtures at different DMM blending ratios were measured under specific conditions. A detailed DMM-NH3 model was proposed, which accurately predicted the IDTs and laminar flame speeds of NH3/DMM mixtures. The effects of various reactions, such as prompt NO and reburn reactions, recombination reactions, H-abstraction reactions, and disproportionation reactions, on ignition were discussed in detail.